Purdue University Purdue e-pubs International Refrigeration and Air Conditioning Conference School of Mechanical Engineering 2014 Low Global Warming Potential Alternative Refrigerants Evaluation Program (Low-GWP AREP) Summary of Phase I Testing Results Xudong Wang Air-Conditioning, Heating, and Refrigeration Institute, United States of America, xwang@ahrinet.org Karim Amrane Air-Conditioning, Heating, and Refrigeration Institute, United States of America, karmane@ahrinet.org Follow this and additional works at: http://docs.lib.purdue.edu/iracc Wang, Xudong and Amrane, Karim, " Low Global Warming Potential Alternative Refrigerants Evaluation Program (Low-GWP AREP) Summary of Phase I Testing Results" (2014). International Refrigeration and Air Conditioning Conference. Paper 1416. http://docs.lib.purdue.edu/iracc/1416 This document has been made available through Purdue e-pubs, a service of the Purdue University Libraries. Please contact epubs@purdue.edu for additional information. Complete proceedings may be acquired in print and on CD-ROM directly from the Ray W. Herrick Laboratories at https://engineering.purdue.edu/ Herrick/Events/orderlit.html
2250, Page 1 Low Global Warming Potential Alternative Refrigerants Evaluation Program (Low-GWP AREP) Summary of Phase I Testing Results Xudong WANG, Karim AMRANE * Air-Conditioning, Heating, and Refrigeration Institute, Arlington, Virginia, USA Tel: 703-524-8800, Fax: 703-562-1942 xwang@ahrinet.org, kamrane@ahrinet.org * Corresponding Author ABSTRACT The Air-Conditioning, Heating, and Refrigeration Institute () recently completed the first phase of its low global warming potential alternative refrigerants evaluation program (Low-GWP AREP). This industry-wide cooperative research program identified and evaluated promising alternative refrigerants performance over the past two years. Thirty-eight low-gwp refrigerants were tested during the first phase of the program in a variety of products; including air conditioners, heat pumps, chillers, ice makers and commercial bottle coolers. This paper provides a comprehensive summary of the test results obtained during phase I. Furthermore, launched a second phase of testing at the beginning of 2014 that includes newly developed refrigerants and performance testing under high ambient conditions that were not covered in the first phase. 1. INTRODUCTION is currently leading an industry-wide cooperative research program, the Low Global Warming Potential Alternative Refrigerants Evaluation Program (Low-GWP AREP). The program aims at identifying and evaluating promising low-gwp alternative refrigerants for major air conditioning and refrigeration products. Phase I testing of the program was completed at the end of 2013. Phase I included compressor calorimeter testing, system testing, and soft-optimized system testing. Thirty-eight refrigerant candidates were tested by twenty one U.S. and international manufacturers and laboratories. The intent of the program is to help industry select promising alternative refrigerants, understand technical challenges and identify the research needed to use these refrigerants. The program s objectives are to identify potential replacements for high GWP refrigerants and present the performance of these replacements in a consistent and standard manner. However, the program will not prioritize the alternative refrigerants. This paper is an overall summary of the test results obtained in Phase I. 2. LOW GWP REFRIGERANTS The tested refrigerants and their compositions are listed in Table 1. These refrigerants were proposed by refrigerant manufacturers and members of the technical committee overseeing the program. Neither an upper numerical limit on refrigerants GWP values nor the safety classifications were limitations to nominating refrigerants, as long as a candidate low-gwp refrigerant had a significant reduction in its GWP relative to the refrigerant it is intended to replace.
2250, Page 2 Table 1: List of low GWP refrigerant candidates in Phase I Baseline Refrigerant Composition (Mass%) Classification (Note 1) GWP 100 (Note 2) ARM-32a R-32/R-125/R-134a/R-1234yf (25/30/25/20) A1 1577 LTR4X R-32/R-125/R-134a/R-1234ze(E) (28/25/16/31) A1 1295 N20 R-32/R-125/R-134a/R-1234yf/R-1234ze(E) (12.5/12.5/31.5/ 13.5/30) A1 975 R22 D52Y R-32/R-125/R-1234yf (15/25/60) A2L 979 L20 R-32/R-152a/R-1234ze(E) (45/20/35) A2L 331 LTR6A R-32/R-744/R-1234ze(E) (30/7/63) A2L 206 R290 R290 100 A3 11 R1270 R1270 100 A3 11 AC5X R-32/R-134a/R-1234ze(E) (7/40/53) A1 622 ARM-41a R-32/R-134a/R-1234yf (6/63/31) A1 943 D-4Y R-134a/R-1234yf (40/60) A1 574 N13a R-134a/R-1234yf/R-1234ze(E) (42/18/40) A1 604 N13b R-134a/R-1234ze(E) (42/58) A1 604 R-134a XP-10 R-134a/R-1234yf (44/56) A1 631 AC5 R-32/R-152a/R-1234ze(E) (12/5/83) A2L 92 ARM-42a R-134a/R-152a/R-1234yf (7/11/82) A2L 117 R1234yf R1234yf 100 A2L 4 R1234ze R1234ze 100 A2L 6 R600a R600a 100 A3 11 R290/R600a R290/R600a (40/60) A3 11 ARM-32a R-32/R-125/R-134a/R-1234yf (25/30/25/20) A1 1577 DR-33 R-32/R-125/R-134a/R-1234yf (24/25/26/25) A1 1410 N40a R-32/R-125/R-134a/R-1234yf/R-1234ze(E) (25/25/21/9/20) A1 1346 N40b R-32/R-125/R-134a/R-1234yf (25/25/20/30) A1 1331 ARM-30a R-32/R-1234yf (29/71) A2L 199 R404A ARM-31a R-32/R-134a/R-1234yf (28/21/51) A2L 491 D2Y65 R-32/R-1234yf (35/65) A2L 239 DR-7 R-32/R-1234yf (36/64) A2L 246 L40 R-32/R-152a/R-1234yf/R-1234ze(E) (40/10/20/30) A2L 285 R-32 R-32 100 A2L 675 R-32/R-134a R-32/R-134a (50/50) A2L 1053 R410A R290 R-290 100 A3 11 ARM-70a R-32/R-134a/R-1234yf (50/10/40) A2L 482 D2Y60 R-32/R-1234yf (40/60) A2L 272 DR-5 R-32/R-1234yf (72.5/27.5) A2L 490 HPR1D R-32/R-744/R-1234ze(E) (60/6/34) A2L 407 L41a R-32/R-1234yf/R-1234ze(E) (73/15/12) A2L 494 L41b R-32/R-1234ze(E) (73/27) A2L 494 R32 R32 100 A2L 675 R-32/R-134a R-32/R-134a (95/5) A2L 713 R-32/R-152a R-32/R-152a (95/5) A2L 647 Notes: 1. Refrigerants classifications or intended classifications according to the ASHRAE 34 (ASHRAE, 2010). 2. Estimated GWP values from chemical producers 3. TESTING Tests conducted during Phase I of the program included: (1) compressor calorimeter tests, (2) system tests, and (3) soft-optimized system tests. Compressor calorimeter tests were conducted in accordance with ASHRAE 23-2010 (testing companies in Europe may alternatively use EN 13771.). The tests were conducted with the alternative refrigerants placed in systems designed for baseline refrigerants with only minor adjustment, if any, such as charge or superheat setting. Soft-optimized tests were performed using baseline refrigerant systems. These systems were modified for the alternative refrigerants using standard production line components. In addition, the heat transfer area of the soft-optimized system s evaporator and condenser may be changed, provided that the
2250, Page 3 sum of the total area remains the same as the baseline system. Manufacturers conducting tests may change components to get optimized performance, but are required to provide enough information to show these changes. All tests were conducted by following the latest industry-wide accepted standards. The following subsections summarize the low-gwp refrigerants tested, and the type of test conducted in Phase I for different product categories. The corresponding Low-GWP AREP Report Number for particular tested equipment is also listed, in order to direct readers to the detailed test information and results. 3.1 Compressor Calorimeter Tests Ten compressors were tested at four different testing facilities. The compressors included reciprocating, scroll, and rotary types. Specific information on the tested compressors is listed in Table 2. No. 1 2 3 4 5 6 7 8 9 10 Compressor Type reciprocating reciprocating reciprocating reciprocating reciprocating scroll scroll scroll scroll rotary Table 2: Tested compressors with low-gwp refrigerants Voltage Displacement Baseline Volume Refrigerant Refrigerants Tested 220/240V, single phase, 50Hz 34.38 cm 3 R-22 R-1270 220/240V, single phase, 50Hz 6.36 cm 3 R-134a ARM-42a, N-13a 115V, single phase, 60Hz 208/230V, three 47.14cm 3 R-404A DR-7, L-40 phase, 60Hz 115V, single phase, 60Hz 208/230V, single phase, 60 Hz 460V, three phase, 60Hz 208/230V, single phase, 60 Hz 208/230V, single phase, 60Hz 220V, single phase, 50Hz AREP Report No. 17 (Ribeiro et al., 2013a) 18 (Ribeiro et al., 2013b) 16.8cm 3 R-134a R-1234yf 30 (Sedliak, 2013c) 8.77 cm 3 R-404A DR-7, L-40 50.96 cm 3 R-404A ARM-31a, D2Y-65, L-40, and R-32/R- 134a (50/50) 98.04 cm 3 R-404A DR-7, L-40 20.32 cm 3 R-32, R-32/R-134a (94/6), DR-5, L-41a 29.5 cm 3 DR-5, L-41b, R-32 28cm 3 DR-5, R-32 35 and 37 (Rajendran et al., 2014b and d) 28 and 29 (Sedliak, 2013a and b) 21 (Shrestha et al., 2013b) 34 and 36 (Rajendran et al., 2014a and c) 11 and 33 (Shrestha et al., 2013a and 2014) 24, 38 and39 (Rajendran et al., 2013, 2014e and f) 26 and 40 (Zhang et al., 2013 a and 2014) 3.2 Air-conditioners and Heat Pumps Eleven air-conditioners and heat pumps (air-source and water-source) were tested with different low-gwp refrigerants. Information about the equipment tested and the type of tests conducted is summarized in Table 3. 3.3 Chillers Six chillers were tested in Phase I. These chillers ranging from 5-ton to 230-ton capacity included both air-cooled and water-cooled products. The test information is shown in Table 4. 3.4 Refrigeration Equipment Two commercial ice machines, one trailer refrigeration unit and one commercial bottle cooler/freezer were tested by three manufacturers participating in the program. Information about the equipment tested and the test procedures is summarized in Table 5.
Unit No. 1 2 3 4 5 6 7 8 Equipment Type 5-ton air source, split system 3.5-ton air source, split system 3-ton air source, split system 3-ton air source, split system 3-ton air source, split system 2-ton air source, split system 8-ton air-source, VRF 3-ton water-to water Baseline Refrigerant 2250, Page 4 Table 3: Tested air-conditioners and heat pumps Refrigerants Tested Test type Test AREP Report No. R-32/R-152a (95/5) 3 (Tio et al., 2012) R-32, R- 1234yf for R-32, softoptimization for R- 1234yf 4, 10 (Crawford et al., 2012), (Uselton, 2013) R-32 soft-optimization 5 (Li et al., 2012) 210/240 R-32, D2Y- 60, L-41a R-32, ARM- 70a, DR-5, L- 41a, L-41b and softoptimization for D2Y- 60 and L-41a R-32 R-32 9 air-to-water 10 11 bus airconditioning bus airconditioning R-32, R-32/R- 134a (95/5), DR-5 ARM-70a, DR-5 and soft optimization for DR-5 R-134a AC5, N-13a R-407C D52Y, L-20 1230 ISO 13256-2 551/591 OEM defined conditions OEM defined conditions 20, 23, 32 (Alabdulkarem et al., 2013a, b and c) 22 (Burns et al., 2013) 31 (Zhang et al., 2013 b) 15 (Tsujii et al., 2013) 16 (Lim et al., 2013) 27 (Besbes et al., 2013) 12 (Kopecka et al., 2013b) 13 (Kopecka et al., 2013c) Unit No. 1 2 3 4 5 6 Equipment Type 5-RT Air-Cooled Water Chiller 5-RT Air-Cooled Water Chiller 175-ton Air-Cooled Screw Chiller 230-Rt Water-Cooled screw Chiller 200 RT Air-Cooled Screw Chiller Water-cooled Centrifugal Chiller Baseline Refrigerant R-22 Table 4: Tested chillers Refrigerants Tested ARM-32a, ARM-70a, DR-5, HPR1D, L-41a, L-41b, and R-32 ARM-32a, DR-7, L-20, LTR4X, LTR6A, and D52Y Test type R-134a ARM-42a R-134a ARM-42a, N- 13a, N-13b, R-1234ze(E), and Opteon TM XP10 R-134a R1234ze(E) and D4Y R-134a R-1234ze(E) and ARM-42a and softoptimized tests Test AREP Report No. 1 (Schultz et al., 2012) 6 (Schultz et al., 2013a) 14 (Kulankara et al., 2012) 7 (Schultz et al., 2013b) 25 (Kasai et al., 2013) Not published, in revision
Unit No. 1 2 3 4 Equipment Type self-contained air-cooled commercial ice machine a split system air-cooled commercial ice machine commercial bottle cooler/freezer trailer refrigeration unit Baseline Refrigerant 2250, Page 5 Table 5: Tested refrigeration equipment Refrigerants Tested Test type Test AREP Report No. 810 and ASHRAE 29 2 (Schlosser, 2012) R-404A L-40, N-40b L-41a R404A L-40, N-40b L-41a R-134a R-404A R-1234yf, R- 1234ze(E), XP- 10, N-13a ARM-30a, DR-7, L-40 810 and ASHRAE 31 810 and ASHRAE 30 810 and ASHRAE 32 2 (Schlosser, 2012) 2 (Schlosser, 2012) 2 (Schlosser, 2012) ASHRAE 72 8 (Shapiro, 2013) 1110 4. TEST RESULTS SUMMARY 9 (Kopecka et al., 2013a) Test results are summarized according to equipment types. The performance of the low GWP refrigerants is normalized to their baseline refrigerants. Therefore, the comparison figures only show their relative performance to their respective baselines. It needs to be pointed out that graphs show only some of the results (e.g. at one particular test conditions, a particular baseline refrigerant etc.) due to the page limit. Readers should refer to the individual test reports for all the data. 4.1 Compressors The results shown in this subsection were obtained from experimental data only. Some test companies generated compressor performance maps in accordance with 540. These maps were used to predict the performance of the compressors at any given set of evaporating and condensing temperatures within the operating envelopes. However, performance ratios predicted in this manner are not included on the figures below. Figure 1 shows the test results of compressors No. 5 and 6 in Table 2 (Sedliak, 2013a and b, Shrestha et al., 2013b). The compressors were tested at different sets of evaporator dew point and condenser dew point temperatures. Only tests having same/similar evaporating dew point (~-20 C and -12 C) and relatively close condenser dew point (43 C and 45 C) are normalized in the figure. The T_eavp dew/t_cond dew for each data point is shown in the figure. The compressors were tested under two different sets of superheat (11K and 22K). The five low GWP refrigerants have higher COP (3%~11%) at 11K superheat compared to R-404A; however only D2Y65 and R-32/R-134a (50/50) could maintain slightly higher or similar capacity (-0.1%~3%) at the same time. The other three refrigerants had some capacity degradation although the degree varies (-13%~-2%). When the compressors were tested at higher superheat (22K), the low GWP refrigerants performance decreased. Their relative capacity decreased further apart from the R-404A (-15%~-4%), and relative COP got closer to the R-404A. For the R-32/R-134a mixture, its COP decreased significantly when the superheat changed from 11K to 22K.
2250, Page 6 Figure 1: Low GWP refrigerants relative performance to R-404A 4.2 Air-conditioners and Heat Pumps Test results for residential air-source air-conditioners and heat pumps are summarized in Figures 2 and 3 (Unit No.1~7 in Table 3). The relative cooling and heating performance to the baseline under standard rating conditions is shown in Figure 2; while Figure 3 shows the relative seasonal performance. Some refrigerants were tested in multiple units (i.e. R-32, L-41a) from different manufacturers. In general, Figure 2 shows that R-32 had higher capacity than ; however, the test results did not show consistency in the efficiency as the results are scattered. This inconsistency could be from variations in the equipment, or test facilities and test conditions. This deserves further investigation in the future. The R-32/R-152a (95/5) mixture showed improvement in capacity and COP. All other blends had different performance than on a basis. Some of them were significantly lower in both cooling and heating capacity than. Most of them showed improvements in the Heating Seasonal Performance Factor (HSPF) and a decrease in the Seasonal Energy Efficiency Ratio (SEER). It should be stressed that these results were obtained from or simple soft-optimization tests and that the equipment tested was designed for and not specifically designed/optimized for these alternative refrigerants. Additional study is needed to evaluate potential improvements through further soft optimization. Figure 2: Low GWP refrigerants relative performance to in air-source air-conditioners and heat pumps
2250, Page 7 Figure 3: Low GWP refrigerants relative seasonal performance to in air-source air-conditioners and heat pumps 4.3 Refrigeration Equipment L-40 and N-40b were tested as refrigerants in two commercial ice machines. One was a self-contained aircooled commercial ice machine and another was a split system. Figure 4 illustrates the low GWP refrigerants relative performance to the baseline R404A at the rating condition (ambient temperature: 32 C; water temperature 21 C) (Schlosser, 2012). N-40b appears to be a direct for the self-contained ice machine at least in terms of the capacity and efficiency. It also showed an increased capacity (~3%), and reduced power consumption (~3%) compared to R-404A for the split system. The L-40 had completely opposite results for the self-contained and the split systems. It performed better in self-contained system and worse in the split system than R-404A did. Figure 4: Low GWP refrigerants relative performance to R-404A in commercial ice machines 4.4 Chillers Two air-cooled and one water-cooled screw chillers were tested. Their capacity ranges from 175 tons to 230 tons. Figure 5 demonstrates the normalized test results to the baseline R-134a at the full-load condition (Kulankara et al., 2012, Kasai et al., 2013, Schultz et al., 2013b). They showed comparable efficiency than R-134a (-4%~6%) for the drop in test. D4Y, XP-10, and ARM-42a showed similar capacity than R-134a, but the efficiency was slightly lower (no more than 4% reduction). The other tested refrigerants showed 10%~25% capacity reduction.
2250, Page 8 Figure 5: Low GWP refrigerants relative performance to R-134a in screw chillers 5. CONCLUSIONS AND FUTURE WORK The test results obtained from the Low-GWP AREP Phase I show that there are several alternative candidates with comparable performance than the baseline refrigerants they intend to replace. However, based on current test results, it appears unlikely that a single refrigerant will replace R-22, R-134a, R-404A, and. Indications point to different alternatives for different applications. It should be noted that most results were obtained from and soft-optimized tests performed on equipment designed for the baseline refrigerants and not the alternatives. Therefore, the results should not be viewed as universally applicable. Additional study is required to evaluate the potential improvement through further soft optimization. Full optimization of systems will likely improve the performance of these refrigerants; however, this work is outside the scope of the Low-GWP AREP, and will be undertaken by individual manufacturers. In some cases, test results showed some inconsistency. This may be due to testing different types and sizes of equipment by different manufacturers using different testing facilities. This would warrant further investigation in the future. Finally, launched Phase II of the Low-GWP AREP in January, 2014. Phase II of the program will focus in areas not previously addressed such as testing refrigerants at high ambient conditions (i.e., warmer climates); evaluating refrigerants in applications not tested in the first phase; and assessing the performance of new refrigerants identified since the program began in 2011. REFERENCES Alabdulkarem, A., Hwang, Y., Radermacher, R., 2013a, System Drop-In Tests of Refrigerants R-32, D2Y-60, and L-41a in Air Source Heat Pump, Low-GWP AREP Report NO. 20 Alabdulkarem, A., Hwang, Y., Radermacher, R., 2013b, System Soft-Optimized Test Of Refrigerant L-41a in Air Source Heat Pump, Low-GWP AREP Report NO. 23 Alabdulkarem, A., Hwang, Y., Radermacher, R., 2013c, System Soft-Optimized Test of Refrigerant D2Y60 in Air Source Heat Pump, Low-GWP AREP Report NO. 32 ASHRAE, 2010, ASHRAE 34: Designation and Safety Classification of Refrigerants, American Society of Heating, Refrigerating, and Air-Conditioning Engineers, Inc.
2250, Page 9 Besbes, K., Zoughaib, A., 2013, System Drop-In Test of Refrigerant Blend ARM-70a and DR-5 in An Air to Water Heat Pump, Low-GWP AREP Report NO. 27 Burns, L., Austin, M., Chen C., 2013, System Drop-in Testing of Replacements in Split System Heat Pump, Low-GWP AREP Report NO. 22 Crawford, T., Uselton, D., 2012, System Drop-in Test of Refrigerant R-32 in Split System Heat Pump, Low-GWP AREP Report NO. 4 Kasai, K., Johnson, P., 2013, System Drop-in Test of R134a Alternative Fluids R-1234ze(E) and D4Y in a 200 RT Air- Cooled Screw Chiller, Low-GWP AREP Report NO. 25 Kopecka, M., Hegar, M., Sulc, V., Berge, J., 2013a, System Drop-In Tests of Refrigerant Blends L-40, DR-7 and ARM- 30a in a Trailer Refrigeration Unit Designed for R-404A, Low-GWP AREP Report NO. 9 Kopecka, M., Hegar, M., Sulc, V., Berge, J., 2013b, System Drop-In Tests of Refrigerant Blends N-13a and AC5 in Bus Air-Conditioning Unit Designed for R-134a, Low-GWP AREP Report NO. 12 Kopecka, M., Hegar, M., Sulc, V., Berge, J., 2013c, System Drop-In Tests of Refrigerant Blends L-20 and D52Y in Bus Air-Conditioning Unit Designed for R-407C, Low-GWP AREP Report NO. 13 Kulankara, S., McQuade, W., 2013, System Drop-In Test of Refrigerant Blend ARM-42a in an Air-Cooled Screw Chiller, Low-GWP AREP Report NO. 14 Li, H., By, B., 2012, Soft-optimized System Test of Refrigerant R-32 in 3-ton Split System Heat Pump, Low-GWP AREP Report NO. 5 Lim, E., Hern, S., 2013, System Drop-in Test of Refrigerant Blend R-32/R-134a (95/5), R-32, and DR-5 in Water-To- Water Heat Pump, Low-GWP AREP Report NO. 16 Rajendran, R., Nicholson, A., 2013, Compressor Calorimeter Test of Refrigerant DR-5 in a Scroll Compressor, Low-GWP AREP Report NO. 24 Rajendran, R., Nicholson, A., 2014a, Compressor Calorimeter Test of Refrigerant DR-7 in a R-404A Scroll Compressor, Low-GWP AREP Report NO. 34 Rajendran, R., Nicholson, A., 2014b, Compressor Calorimeter Test of Refrigerant DR-7 in a R-404A Reciprocating Compressor, Low-GWP AREP Report NO. 35 Rajendran, R., Nicholson, A., 2014c, Compressor Calorimeter Test of Refrigerant L-40 in a R-404A Scroll Compressor, Low-GWP AREP Report NO. 36 Rajendran, R., Nicholson, A., 2014d, Compressor Calorimeter Test of Refrigerant L-40 in a R-404A Reciprocating Compressor, Low-GWP AREP Report NO. 37 Rajendran, R., Nicholson, A., 2014e, Compressor Calorimeter Test of Refrigerant L-41b in a Scroll Compressor, Low-GWP AREP Report NO. 38 Rajendran, R., Nicholson, A., 2014f, Compressor Calorimeter Test of Refrigerant R-32 in a Scroll Compressor, Low-GWP AREP Report NO. 39 Ribeiro, G. B., Gennaro, G. M. D., 2013a, Compressor Calorimeter Test of Refrigerants R-22 and R-1270, Low- GWP AREP Report NO. 17 Ribeiro, G. B., Gennaro, G. M. D., 2013b, Compressor Calorimeter Test of Refrigerants R-134a, N-13a and ARM-42a, Low-GWP AREP Report NO. 18 Ribeiro, G. B., Gennaro, G. M. D., 2013c, Compressor Calorimeter Test of Refrigerants R-134a and N-13a, Low- GWP AREP Report NO. 19
2250, Page 10 Schlosser, C., 2012, System Drop-in Test of L-40, L-41a and N-40b in Ice Machines, Low-GWP AREP Report NO. 2 Schultz, K., Kujak, S., 2012, System Drop-in Test of Alternative Fluids (ARM-32a, ARM-70a, DR-5, HPR1D, L- 41a, L-41b, and R-32) in a 5-RT Air-Cooled Water Chiller (Cooling Mode), Low-GWP AREP Report NO. 1 Schultz, K., Kujak, S., 2013a, System Drop-in Tests of R-22 Alternative Fluids (ARM-32a, DR-7, L-20, LTR4X, LTR6A, and D52Y) in a 5-RT Air-Cooled Water Chiller (Cooling Mode), Low-GWP AREP Report NO. 6 Schultz, K., Kujak, S., 2013b, System Drop-In Tests of R134a Alternative Refrigerants (ARM-42a, N-13a, N-13b, R- 1234ze(E), and OpteonTM XP10) in a 230-RT Water-Cooled Water Chiller, Low-GWP AREP Report NO. 7 Sedliak, J., 2013a, Compressor Calorimeter Test of R-404A Alternative Refrigerant L-40 in Reciprocating Compressors, Low-GWP AREP Report NO. 28 Sedliak, J., 2013b, Compressor Calorimeter Test of R-404A Alternative Refrigerant DR-7 in Reciprocating Compressors, Low-GWP AREP Report NO. 29 Sedliak, J., 2013c, Compressor Calorimeter Test of R-134a Alternative Refrigerant R-1234yf in Reciprocating Compressors, Low-GWP AREP Report NO. 30 Shapiro, D., 2013, System Drop-In Tests of R-134a, R-1234yf, OpteonTM XP10, R-1234ze(E), and N13a in a Commercial Bottle Cooler/Freezer, Low-GWP AREP Report NO. 8 Shrestha, S., Mahderekal, I., Sharma, V., Abdelaziz, O., 2013a, Compressor Calorimeter Test of Alternatives R- 32, DR-5, and L-41a, Low-GWP AREP Report NO. 11 Shrestha, S., Sharma, V., Abdelaziz, O., 2013b, Compressor Calorimeter Test of R-404A Alternatives ARM-31a, D2Y-65, L-40, and R-32/R-134a (50/50), Low-GWP AREP Report NO. 21 Shrestha, S., Sharma, V., Abdelaziz, O., 2014, Compressor Calorimeter Test of Alternative: R-32/R-134a Mixture Using a Scroll Compressor, Low-GWP AREP Report NO. 33 Tio, E., Linkous, R., Durfee, N., Abdelaziz, O., 2012, System Drop-in Test of R-32/R-152a (95/5) in a 5-ton Air Source Heat Pump, Low-GWP AREP Report NO. 3 Tsujii, H., Imada, H., 2013, System Drop-In Test of Refrigerant R-32 in a VRF Multi-split Heat Pump, Low-GWP AREP Report NO. 15 Uselton, D., 2013, System Soft-Optimized Test Of Refrigerant HFO-1234yf (R-1234yf) in a Split System Heat Pump, Low-GWP AREP Report NO. 10 Zhang, L., Zhu, Y., Qin, C., 2013a, Compressor Calorimeter Test of Refrigerant R-32 in a Rotary Type Compressor, Low-GWP AREP Report NO. 26 Zhang, L., Zhu, Y., 2013b, System Drop-in Test of Refrigerant R-32 in Split Air-conditioning System, Low-GWP AREP Report NO. 31 Zhang, L., Zhu, Y., Qin, C., 2014, Compressor Calorimeter Test of Refrigerant DR-5 in a Rotary Type Compressor, Low-GWP AREP Report NO. 40 ACKNOWLEDGEMENT The Low-GWP AREP is strongly desired and supported by the HVACR industry. Nineteen industry experts provide technical guidance and oversee the program. Six chemical producers supply refrigerant samples for testing. Twenty-one entities, internationally and domestically, including OEMs, universities and national laboratories, conducted various tests. gratefully thanks all of them for contributing their expertise and resources to the program.